DOI : 10.17577/IJERTV7IS010143
- Open Access
- Total Downloads : 328
- Authors : Venkada Seenivasan N , Devaki H
- Paper ID : IJERTV7IS010143
- Volume & Issue : Volume 07, Issue 01 (January 2018)
- DOI : http://dx.doi.org/10.17577/IJERTV7IS010143
- Published (First Online): 25-01-2018
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License:
This work is licensed under a Creative Commons Attribution 4.0 International License
Study on Effects of Fly-Ash and Tamarind Kernel Powder in Concrete
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Venkada Seenivasan.M.E
Assistant Professor Department of Civil Engineering KGiSL Institute of Technology
Saravanampatti,Coimbatore
H.Devaki.M.Tech Assistant Professor
Department of Civil Engineering KGiSL Institute of Technology Saravanampatti,Coimbatore
AbstractThe conventional concrete has lost its usage in modern days as it does not serve the present needs. Hence in order to improve the properties of the concrete in the fresh and the hardened state, high performance concrete (HPC) is used. When using tamarind in concrete possess high workability, high strength, high dimensional stability, high durability, low permeability and resistance to chemical attack.This project deals with the effects of supplementary cementations materials in concrete by incorporating fly ash and tarmarind with a water binder ratio of 0.3.Here the conventional concrete is obtained by ordinary Portland cement is replaced with 10%, 20% 30% 40% and 50% of fly ash and also partial replacement of sand by tamarind powder From the experimental results, it is observed that concrete exhibits improved compressive strength, split tensile strength and flexural strength when compared with the conventional mix.
Keywords High performance concrete, fly ash, Tarmarind.
Hardened properties
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INTRODUCTION
In this chapter, a brief review of the findings of earlier investigations on the important properties parameters of fly ashes; the available literature on the mechanisms of lime-fly ash and cement-fly ash hydration processes influence of fly ash addition on the properties of concrete, workability and compressive strength , have been presented. A comprehensive review of the work of earlier investigators on blended cements; studies on the activation of low-calcium and high- calcium fly ashes and pozzolonas, have been also presented. An attempt has also been made to critically evaluate the status of activation studies on fly ash. Apart from the above, literature relevant to the work carried out in this study, namely, on mix proportioning methods; effect of elevated temperature; influence of various aggressive environments on blendedfly ash concretes, been briefly reviewed and presented.
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MATERIALS
TABLE 2.1.2 CHEMICAL COMPOSITION OF FLY ASH
Sl. No.
Chemical component
% of chemical component
1.
SiO2
42
2.
Fe2O3
28
3.
Al2O3
22
4.
CaO
2
5.
MgO
1
6.
K2O
1.30
7.
Na2O
0.30
8.
SO3
1
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uper plasticizers
The new generation super plasticizer- 400 was used.
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Colour – Brown
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Type – Liquid
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Specific gravity – 1.175 at 300
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Storage condition – in cool dry place shelf life – 1 year
The mix proportion were designed as per I.S.10262-2009, 1:1.23:2.19:0.38 (cement: fine aggregate: coarse aggregate: water) by weight of cement was used throughout.
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RESULT
A. Workability
Workability of the high performance concrete is determined using slump test and the values are tabulated in Table 4.1.1
Sample
%
m
p
Normal concrete with in PCC
0
55
Normal concrete with in OPC
0
55
OPC concrete replacement of sand with Tamarind
100
52
OPC concrete replacement of cement with in flyash
10
51
OPC concrete replacement of cement with in flyash
20
50
OPC concrete replacement of cement with in flyash
30
44
OPC concrete replacement of cement with in flyash
40
43
OPC concrete replacement of cement with in flyash
50
40
TABLE 4.1.1 WORKABILITY TEST RESULTS
A. Fly Ash
Flyash is a by-product of the combustion of pulverized coal in thermal power plants. Flyash exhibits pozzolanic activity.
TABLE 2.1.1 PHYSICAL PROPERTIES OF FLY ASH
Sl. No.
Particulars
Values
1
Specific gravity
2.04
2
Fineness modulus
2.16
3
Consistency
29%
4
Initial setting time
110 minutes
5
Final setting time
235 minutes
B.Compressive Strength
Cubes and cylinder are casted and its values are tabulated and plotted.
7 and 28 Days of cube compressive Strength for M30 Grade
40
7 and 28 Days flextural Strength for M30 Grade
35 34.13 33.54
32.35
28
30
25
.17
25.37
27.46
6
5 4.8
4.58 4.33 4.31 4.4
20
15
10
5
0
30% TR 10%
flyash
20%
flyash
30%
flyash
40%flyasp0%flyash
7days
28 days
4 4
4 3.74
3
3
2
1
3.61 3.67 3.58
7 days
28 days
Fig 1 Cube compressive strength
0
30% TR 10%
20%
30%
40%
50%
Flyash Flyash Flyash Flyash Flyash
7 and 28 Days Cylinder compressive Strength for M30 Grade
35
30.44 30.04
25.9
30
18.7
25
14.9
15.8
13.6
8
20
7
7
15
10
5
0
26.2
6
23.42
13.7
14.1
21.72
4
5
7days 28days
Fig 4 Flexural strength
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CONCLUSION
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-
The dosage of tamarind and fly ash has a significant effect on the compressive strength of concrete under normal curing. The concrete mixture with 10% Fly ash (M1) shows an improved compressive strength than concrete with 20% FA (M2)and the strength goes on decrease with 30%(M3),40%(M4),50%(M5) replacement at 7 days and
28days. The increase in curing period increases the
30%TR 10%
flyash
20%
flyash
30%flyash 40%flyash 50%flyash
strength of M1 concrete specimens and M2 concrete specimens at 7 and 8 days.
Fig 2 Cylinder compressive strength
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Split tensile Strength
Cylinder is casted and its split tensile strength are determined and plotted.
7 and 28 days Split Tensile Strength for M30 Grade
6
-
The curing of 7 and 28 days compressive strength of (Tamarind+FA) mixture incorporating 30%, 40% and 50% FA was lower than control concrete under normal curing. This is because the pozzolanic reaction is slow and the formation of calcium hydroxide requires time.
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It is evident from the experimental resuts that the compressive strength decreases when the percentage of fly ash increases.
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The flexural strength similar to the compressive strength shows better results for 10 % and 20% replacement of fly
5
4 3.7
3
2 1.5
1
0
4.78
2.1
4.11 3.91
1.58 1.38
3.52 3.66
1.3 1.21
7days 28 days
ash and 30% replacement of tamarind powder instead of sand but it got reduced with 40% and 50% replacement Further mixes concludes that 10% and 20% replacement of fly ash gives a optimum strength for M30 Grade concrete compared to other replacement.
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-
D.Brindha ,Baskaran.(2010)Durability studies on copper slag admixed
30% TR 10% Fly
ash
20%
flyash
30%
flyash
40%
flyash
50%
flyash
concrete, Asian journal of civil engineering (Building and housing),
Vol.12, No.5 563-578
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Bouzoubaa and others (2001) Utilization of Copper Slag as a Partial Replacement of Fine Aggregate in Concrete International Journal of
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-
Flexural strength
Fig 3 Split tensile strength
Earth Sciences and Engineering Vol. 03, pp. 579-585
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